A new computational model could potentially boost efficiencies and profits in natural gas production by better predicting previously hidden fracture mechanics while accurately accounting for the known amounts of gas released during the process.

By considering the closure of preexisting fractures caused by tectonic events in the distant past and taking into account water seepage forces not previously considered, researchers from Northwestern Engineering and Los Alamos developed a new mathematical and computational model that shows how branches form off vertical cracks during the fracking process, allowing more natural gas to be released.

The model is the first to predict this branching while being consistent with the known amount of gas released from the shale during this process. The new model could potentially increase the industry’s efficiency. The results were published in the Proceedings of the National Academy of Sciences.

Our model is far more realistic than current models and software used in the industry. This model could help the industry increase efficiency, decrease cost, and become more profitable.

Despite the industry’s growth, much of the fracking process remains mysterious. Because fracking happens deep underground, researchers cannot observe the fracture mechanism of how the gas is released from the shale.

Schematic branching due to natural fractures. (A) Water is injected at high pressure through damaged zones and weak layers, (B) crack branching initiates due to the presence of damaged zones and natural fractures, and (C) dense cracking happens in all directions, due to the presence of dam-aged zones, weak layers at closed natural fractures.

This work offers improved predictive capability that enables better control of production while reducing the environmental footprint by using less fracturing fluid. It should make it possible to optimize various parameters such as pumping rates and cycles and changes of fracturing fluid properties such as viscosity. This could lead to a greater percentage of gas extraction from the deep shale strata, which currently stands at about 5 percent and rarely exceeds 15 percent.

Understanding just how the shale fractures form could also improve management of sequestration, where wastewater from the process is pumped back underground.

To extract natural gas through fracking, a hole is drilled down to the shale layer—often several kilometers beneath the surface—then the drill is extended horizontally for miles. When water with additives is pumped down into the layer under high pressure, it creates cracks in the shale, releasing natural gas from its pores of nanometer dimensions.

Classic fracture mechanics research predicts that those cracks, which run vertically from the horizontal bore, should have no branches. But these cracks alone cannot account for the quantity of gas released during the process. In fact, the gas production rate is about 10,000 times higher than calculated from the permeability measured on extracted shale cores in the laboratory.

Other researchers previously hypothesized the hydraulic cracks connected with pre-existing cracks in the shale, making it more permeable.

Bažant and his fellow researchers found that these tectonically produced cracks, which are about 100 million years old, must have been closed by the viscous flow of shale under stress.

Instead, Bažant and his colleagues hypothesized that the shale layer had weak layers of microcracks along the now-closed cracks, and it must have been these layers that caused branches to form off the main crack. Unlike previous studies, they also took into account the seepage forces during diffusion of water into porous shale.

When they developed a simulation of the process using this new idea of a weak layers, along with the calculation of all the seepage forces, they found the results matched those found in reality.

We show, for the first time, that cracks can branch out laterally, which would not be possible if the shale were not porous.

—Zdeněk Bažant

After establishing these basic principles, researchers hope to model this process on a larger scale.

This research was funded by the Laboratory Directed Research and Development program at Los Alamos National Laboratory, and the collaborating team at Los Alamos was funded by the Office of Basic Energy Sciences of the Department of Energy.